초록 ▼

A pair of zero-turn, hydrostatic transaxles (HZTs) that may be joined to form an integrated, zero-turn, hydrostatic transaxle. Each of the hydrostatic transaxles are further comprised of a casing carrying a hydraulic pump driven by an input shaft, a hydraulic motor driven by a the hydraulic pump thr

A pair of zero-turn, hydrostatic transaxles (HZTs) that may be joined to form an integrated, zero-turn, hydrostatic transaxle. Each of the hydrostatic transaxles are further comprised of a casing carrying a hydraulic pump driven by an input shaft, a hydraulic motor driven by a the hydraulic pump through porting contained within a center section, and an axle shaft driven by the hydraulic motor. The hydrostatic transaxles are joined along an interface extending generally perpendicularly to the axle shafts.

대표청구항 ▼

What is claimed is: 1. A hydraulic device, comprising: a housing; a center section mounted within the housing; a hydraulic cylinder rotatably mounted on the center section: a bypass mechanism mounted adjacent to the hydraulic cylinder, wherein the bypass mechanism comprises an arm having two opposi

What is claimed is: 1. A hydraulic device, comprising: a housing; a center section mounted within the housing; a hydraulic cylinder rotatably mounted on the center section: a bypass mechanism mounted adjacent to the hydraulic cylinder, wherein the bypass mechanism comprises an arm having two opposing generally flat surfaces connected by a peripheral edge; and a notch formed in the peripheral edge of the arm, whereby the notch is entirely between the two generally flat surfaces and cooperates with a portion of the housing to limit movement of the arm. 2. The hydraulic device as set forth in claim 1, wherein the bypass mechanism further comprises a puck and movement of the bypass mechanism arm causes the puck to engage the hydraulic cylinder to move the hydraulic cylinder away from the center section. 3. The hydraulic device as set forth in claim 2, wherein the bypass mechanism further comprises an actuator and movement of the bypass mechanism arm causes the actuator to force the puck into engagement with the hydraulic cylinder. 4. The hydraulic device as set forth in claim 3, wherein the puck engages an end of the hydraulic cylinder. 5. The hydraulic device as set forth in claim 3, wherein rotation of the arm about the central axis of the actuator causes a cam formed on the actuator to move the puck into engagement with the hydraulic cylinder. 6. The hydraulic device as set forth in claim 3, wherein the actuator has a first retaining ring mounted thereon, and a second retaining ring mounted in the housing forms a stop for the first retaining ring to thereby retain the actuator within the housing. 7. The axle driving device as set forth in claim 3, wherein the actuator has a first retaining ring mounted thereon, and a second retaining ring mounted in the housing forms a stop for the first retaining ring to thereby retain the actuator within the housing. 8. The hydraulic device as set forth in claim 1, further comprising a second hydraulic cylinder mounted on the center section, wherein the second cylinder block is driven by a pump input shaft. 9. The hydraulic device as set forth in claim 8, wherein the bypass mechanism comprises an actuator and the actuator is generally parallel to the input shaft. 10. A bypass mechanism for a hydraulic device having a hydraulic circuit and a housing, the bypass mechanism comprising: an actuator; an arm engaged to the actuator and moveable in two directions, whereby movement of the arm causes the bypass mechanism to be activated to open the hydraulic circuit to a sump; and a single notch formed in a portion of the arm and comprising a pair of edges which cooperate with an external surface of the housing to limit movement of the arm in both directions, whereby one edge of the notch contacts the housing surface at the limit of movement in one direction and the other edge of the notch contacts the housing surface at the limit of movement in the other direction, and the notch does not contact the housing surface when the arm is between the two limits of movement. 11. The bypass mechanism as set forth in claim 10, wherein a center section containing at least a portion of the hydraulic circuit and having a motor cylinder block rotatably mounted thereon is located in the housing, the motor cylinder block being in fluid communication with the hydraulic circuit, and movement of the bypass mechanism arm causes the motor cylinder block to be moved from the center section. 12. The bypass mechanism as set forth in claim 11, wherein the arm may be rotated in a first direction corresponding to the bypass mechanism being disengaged from the motor cylinder block and in a second direction corresponding to the motor cylinder block being moved away from the center section, and the notch comprises a first end limiting movement of the arm in the first direction and a second end limiting movement of the arm in the second direction. 13. The bypass mechanism as set forth in claim 11, wherein a pump cylinder block is rotatably mounted on the center section such that the axis of rotation of the pump cylinder block is generally perpendicular to the axis of rotation of the motor cylinder block and wherein the motor cylinder block is drivingly connected to a plurality of gears mounted in the housing. 14. The bypass mechanism as set forth in claim 13, wherein movement of the arm to the second position permits the plurality of gears to be rotated without causing fluid flow to the pump cylinder block. 15. The bypass mechanism as set forth in claim 13, wherein the actuator is generally parallel to the rotational axis of the pump cylinder block. 16. The bypass mechanism as set forth in claim 10, wherein the arm is retained on the actuator by a retaining ring. 17. An axle driving device, comprising: a housing forming a sump; an axle mounted in the housing and having at least one end of the axle extend out of the housing; a center section mounted within the housing and having a hydraulic circuit formed therein; a pump cylinder block and a motor cylinder block rotatably mounted on the center section and in fluid communication through the hydraulic circuit; a motor output shaft drivingly engaged to the motor cylinder block and providing a driving force to the axle; a pump input shaft extending into the housing and driving the pump cylinder block; a bypass mechanism comprising an actuator mounted in the housing and having a first end located outside the housing, and an arm engaged to the first end, and comprising two generally flat surfaces connected by a peripheral edge, whereby rotation of the arm causes the bypass mechanism to open the hydraulic circuit to the sump; and a notch formed in the peripheral edge of the arm, whereby the notch is entirely between the two generally flat surfaces and cooperates with a portion of the external surface of the housing to limit movement of the arm. 18. The axle driving device as set forth in claim 17, wherein the bypass mechanism further comprises a pack located between the actuator and an end of the motor cylinder block, and movement of the bypass mechanism arm causes the puck to engage the motor cylinder block to move the motor cylinder block off the center section. 19. The axle driving device as set forth in claim 17, wherein actuator is parallel to the pump input shaft. 20. The axle driving device as set forth in claim 18, wherein rotation of the arm about the central axis of the actuator causes a cam formed on the actuator to move the puck into engagement with the motor cylinder block.